Device and method for recovering a non-ferrous metal from hot dross

ABSTRACT

This invention relates to the field of recycling non-ferrous metals (for example, aluminium and alloys thereof, magnesium and zinc). The claimed device comprises: a frame with a dross compression head; an ingot mold for collecting metal compressed from the dross; a dross pot mounted on said ingot mold; at least one through opening with a connection means for supplying a vacuum, said opening being situated in the bottom part of the dross pot and/or in the ingot mold; and a seal, situated in the gap between the dross pot and the ingot mold; furthermore, one or several through drainage openings are provided in the bottom part of the dross pot. The device may comprise a seal between the dross compression head and the dross pot. The head may be provided with one or several ribs. The dross pot may be provided with one or several ribs. The head may be hollow and provided with two or more air-cooling connecting pipes. The device may comprise a cover, sealingly mounted on a rod of a hydraulic cylinder of a device for compressing hot dross such as to be capable of sliding along the rod, said cover sealingly conforming to the edges of the dross pot. The device may comprise a cover, sealingly mounted on a rod of a hydraulic cylinder of a dross press such as to be capable of sliding along the rod with the aid of pneumatic or hydraulic cylinders (1 to 4 in total), said cover sealingly conforming to the edges of the dross pot. The device may comprise a cover, sealingly mounted on a rod of a hydraulic cylinder of a dross press such as to be capable of sliding along the rod, said cover sealingly conforming to the edges of the dross pot, and at least one through opening with a connection means for supplying an inert gas. The device may comprise one or several dross pot vibrators and/or head vibrators, or magnetohydrodynamic (MHD) pumps, for moving the metal toward the one or several drainage openings in the bottom part of the dross pot. The claimed method for recovering a non-ferrous metal from hot dross, preferably aluminium, aluminium alloy, magnesium or zinc dross, comprises the following steps/operations: (a) removing dross to the dross pot of the above-mentioned device; (b) collecting a non-ferrous metal, which is drained through at least one through opening in the bottom part of the dross pot; (c) mechanically compressing the dross by the application of force to the dross between a compression head and the dross pot in order to recover a non-ferrous metal from the dross, enable the migration of the non-ferrous metal in the direction of the surface boundary of the compressed dross, the formation of an outer layer of non-ferrous metal, which encapsulates an inner oxide core of dross between the aforementioned compression head and the dross pot, and the drainage of a portion of the non-ferrous metal through a through opening(s) in the bottom part of the dross pot, and to prevent oxygen from penetrating the non-ferrous metal in the dross; and (d) supplying a vacuum to the bottom part of the dross pot and/or to the ingot mold, which comprises at least one through opening with a connection means for supplying a vacuum, and a seal, situated in en the gap between the dross pot and the ingot mold, the dross pot being provided with one or several through drainage openings in the bottom part thereof; and, simultaneously with (c) and (d), (e) collecting the non-ferrous metal drained through the through opening in the bottom part of the dross pot; and (f) cooling the compressed dross and the non-ferrous metal in order to harden the non-ferrous metal, thus reducing the thermite reaction of the non-ferrous metal and Noxygen in the dross by combining the above-mentioned compression of the dross with the effect of a vacuum and the cooling of the metal. The invention increases the recovery of a non-ferrous metal from dross.

FIELD OF THE INVENTION

The invention relates to recycling of non-ferrous metals, preferably of aluminum, alloys thereof, magnesium, zinc from hot dross removed from melting furnaces, mixers and other thermal apparatuses.

BACKGROUND OF THE INVENTION

Apparatuses for compression of hot dross of non-ferrous metal, preferably aluminum, alloys thereof, magnesium, zinc dross, comprising dross compressing head with ribbed or non-ribbed surfaces and skim pan with or without ribbed surfaces, as well as having one or more through drainage holes in bottom are known in the prior art [1-18].

Apparatus for compression of hot dross of non-ferrous metal, preferably aluminum, alloys thereof, magnesium, zinc dross, comprising frame with dross compressing externally ribbed head of semispherical or elongated semispherical shape; skim pan with one or more through drainage holes in bottom, wherein the skim pan is located on the top of saw mould, which collects drained from dross metal is known in the prior art [19].

The semispherical or elongated semispherical press head is integrated with the skim pan, where within dross compression external metal layers are generated, which are crystallized near the surfaces of said head and skim pan, and internal layer of metal oxide, which is located between the metal layers [19].

Ribbed surfaces of the press head and skim pan provide higher specific pressure onto dross and grooving of the dross, facilitating breakage and subsequent supplemental extraction of metal from frozen pressed dross (skull) [19].

The head is hollow and equipped with forced air or liquid cooling, which reduces dross cooling time and decreases metal oxidation loss [19].

1. It is known a method [20] for recovery of free aluminum metal from a metal bearing dross containing free aluminum metal and oxides of said metal, said method comprising the steps of:

(a) collecting the dross in a receptacle of the type having at least one trough with at least one downwardly and inwardly inclined side wall with metal flow passages through the wall;

(b) collecting the free aluminum metal which decants through the passages;

(c) mechanically compacting the dross by applying a compressive force on the dross and against the inclined wall above a threshold pressure to pool free aluminum metal within a dross, effect migration of the free aluminum metal toward a boundary surface of the compacted dross, decant a portion of said free aluminium through the passage and inhibiting the oxygen supply to the free aluminum metal in the dross; and

(d) cooling the compacted dross and free aluminum metal to solidify the free aluminum metal; such that thermite reaction of free aluminum metal and oxygen in the dross is diminished by the combination of compacting above the threshold pressure and cooling of the metal.

2. It is known the method of claim 1 [20] including the subsequent step of mechanically breaking the compacted dross to recover additional solidified free aluminum metal. 3. It is known the method of claim 2 [2] including the step of separating free aluminum metal from the oxide. 4. It is known the method of claim 1 [20] wherein the threshold pressure of the mechanical compression of the dross in operation © is about 64 pounds per square inch. 5. It is known the method [20] for recovery of free aluminum metal from aluminum metal bearing dross where said dross also includes oxide impurities, said method comprising the steps of:

(a) collecting the dross in a receptacle of the type having at least one trough with at least one downwardly and inwardly inclined sidewall having metal flow passages through the wall;

(b) collecting free aluminum metal which decants through the passages;

(c) mechanically compacting the dross by applying a compressive force on the dross and against the inclined wall above the threshold pressure to pool free aluminum metal within the dross, effect migration of the free aluminum metal toward a boundary surface of the compacted dross, decant a portion of said free aluminum metal thorugh the passages and inhibit the oxygen supply to the free aluminum metal in the dross;

(d) cooling the compacted dross and free aluminum metal to solidify the free aluminum metal; such that thermite reaction of free aluminum metal and oxygen in the dross is diminished by the combination of compacting above the threshold pressure and cooling of the metal;

(e) removing compacted dross from the skimpan;

(g) separating the components of the dross having a larger mean diameter from the remainder of the dross, said larger mean diameter components generally comprising metal, said remainder including a granulate and an oxide dust; and

(h) melting substantially the granulate reminder of the dross to thereby segregate a molten metal portion from the reminder of the dross.

6. It is known the method [21] for the recovery of free aluminum metal from hot aluminum dross which forms on the surface of molten aluminum during aluminum melting operations, said dross containing free aluminum metal and a solids network, said method comprising the steps of:

(a) charging the hot dross from the aluminum melting operation into a receptacle having at least one inclined sidewall and at least one passageway;

(b) mechanically compacting the dross with a heated ram, said compacting applying a compressive force on the dross towards the inclined sidewall such that a substantial portion of the free aluminum separates from the dross and passes through the bottom passageway;

(c) maintaining the temperature of the hot dross during its collection in the receptacle and subsequent mechanical compaction so as to enhance the removal of free aluminum therefrom; and

(d) collecting the free aluminum metal which passes through the bottom passageway.

7. It is known the method [21] wherein the dross is mechanically compacted by applying a series of successive strokes on the dross towards the inclined sidewall. 8. It is known the method [21] wherein 3 to 10 strokes are applied. 9. It is known the method [21] wherein the head external surface and skimpan internal surface can be semi-spherically shaped, conical, concave and convex in shape. 10. It is known the method [21] wherein further comprising cooling the compacted dross after said compacting, said cooling minimizing further oxidation of any free aluminum contained within the compacted dross. 11. It is known the method [21] for the recovery of free aluminum metal from hot aluminum dross which forms on the surface of molten aluminum during aluminum melting operations, said dross containing free aluminum metal and a solids network, said method comprising the steps of:

(a) heating a compressing head and a skimpan to a temperature approximating that of the hot dross to inhibit cooling of the dross during the subsequent charging and mechanical compaction steps, said skimpan having at least one inclined sidewall and at least one passageway extending through the bottom of the skimpan, said bottom passageway being sized and configured to permit the passage of free aluminum and inhibit the passage of said solids network;

(b) charging the hot dross from the aluminum melting operation into the heated skimpan;

(c) mechanically compacting the dross with the heated head by applying a compressive force on the dross towards the inclined sidewall such that a substantial portion of the free aluminum separates from the dross and passes through the bottom passageway; and

(d) collecting the free aluminum metal which passes through the bottom passageway.

12. It is known the method [21] wherein the head and skimpan are heated by directing a flame into a gap existing between the head surface and the skimpan sidewall surface when the head is partially inserted into the skimpan. 13. It is known the method [21] wherein the compressing head and skimpan are heated by embedding heating coils therein. 14. It is known the method [21] for the recovery of free aluminum metal from hot aluminum dross which forms on the surface of molten aluminum during aluminum melting operations, said dross containing free aluminum metal and a solids network, said method comprising the steps of:

(a) charging the hot dross from the aluminum melting operation into a skimpan having at least one inclined sidewall and at least one passageway extending through the bottom of the skimpan said bottom passageway being sized and configured to permit the passage of free aluminum and inhibit the passage of said solids network;

(b) mechanically compacting the dross by applying a compressive force on the dross towards the inclined sidewall such that a substantial portion of the free aluminum separates from the dross and passes through the bottom passage, said compacting being provided by an upward stroke of the skimpan towards a fixed ram;

(c) maintaining the temperature of the hot dross during its collection in the skimpan and subsequent mechanical compaction so as to enhance the removal of free aluminum therefrom; and

(d) collecting the free aluminum metal which passes through the bottom passageway.

A drawback of the aforementioned method [21]is that due to the preliminary heating of the head, and other conditions being equal, the dross cooling cycle time increases, and hence, as a result of longer oxidation time of aluminum, the metal recovery decreases.

A drawback of the aforementioned methods [20,21] and apparatus [1-19] is that the amount of metal, drained from hot dross, the so called in-house metal recovery, is usually relatively lower (from 3 to 20%), than the metal content remaining in dross skull after freezing (from 40 to 70%). Further secondary recovery of metal from frozen dross is as a rule accompanied with its supplemental mechanical and/or thermal treatment (melting), which results in additional metal loss.

It is known the apparatus [22] for recovery of non-ferrous metal from hot dross, comprising a frame with dross compressing head, a saw mould for collection of drained metal from hot dross and a skim pan, provided with one or more through drainage holes in a bottom put on a said saw mould, characterized in that provided with at least one through hole with connection for switching on vacuum through said saw mould wall, sealing located in the gap between said skim pan and said saw mould.

A drawback of the aforementioned prototype [22] is that the location of through hole with connection for switching on vacuum through said saw mould wall, in case of hot dross with high aluminium content (more than 55%), could be a probability overlapping/blocking of the Aforementioned hole by drained metal in saw mould in case of high fullness. It is not allowing to drain more metal into saw mould.

SUMMARY OF INVENTION AND OBJECTS

This invention is aimed at increase in recovery of non-ferrous metal from dross.

Technical result is achieved in the apparatus for recovery of non-ferrous metal from hot dross, preferably aluminum, alloys thereof, magnesium, zinc from hot dross removed from melting furnaces, mixers and other thermal apparatuses, comprising a frame with dross compressing head, a saw mould for collection of drained metal from hot dross and a skim pan put on a said saw mould, characterized in that provided with one or more through holes with connection for switching on vacuum through said skim pan bottom, and sealing located in the gap between said skim pan and said saw mould, wherein said skimpan provided with one or more through drainage holes in a bottom. The location of through holes with connection for switching on vacuum through said skim pan bottom is more preferable, than in saw mould wall. The reason is that through holes with connection for switching on vacuum through said skim pan bottom is always located higher than in saw mould, consequently, less probability for said through hole to be overlapped/blocked by drained metal in case of high fullness. It allows to drain more metal in saw mould.

The apparatus can comprise sealing between the dross compressing head and said skim pan.

The head can be ribbed. The skim pan can be ribbed.

The head can be made hollow with at least two manifolds with air cooling.

The apparatus can comprise hermetic cover, hermetically female the rod of hydraulic cylinder with a possibility of sliding along the rod and hermetically to cover the skim pan.

The apparatus can comprise hermetic cover, hermetically female the rod of hydraulic cylinder with a possibility of sliding along the rod and hermetically to cover the skim pan by means of pneumatic or/and hydraulic cylinders (from 1 to 4 pcs), or/and electric drive.

The apparatus can comprise hermetic cover, hermetically female the rod of hydraulic cylinder with a possibility of sliding along the rod and hermetically to cover the skim pan by means of pneumatic or/and hydraulic cylinders (from 1 to 4 pcs), or/and electric drive and, at least one or more through hole in said cover provided a connection for inert gas supply.

The apparatus can comprise one or more vibrators of said skim pan and/or said head.

The apparatus can comprise one or more magneto-hydrodynamic (MHD) pumps for moving of metal to one or more drainage holes in the bottom of said skim pan.

Vacuum promotes recovery of liquid metal from pores of hot dross and drainage via through holes in the bottom of said skim pan, that is, increases recovery of metal from dross. Vacuum also promotes flow of liquid metal in the layer adjacent to the bottom of the skim pan, accelerates heat and mass transfer, cooling of metal in dross, decreases metal oxidation, increases metal recovery from dross.

Semispherical or elongated semispherical press head is integrated with said skim pan, wherein within dross compression external layers of metal are formed, which are crystallized mainly near surfaces of said head and said skim pan, and internal layer of metal oxide, which is capsulated between the metal layers.

Hot dross compressing head draws off thermal energy from dross due to thermal conductivity and thermal capacity, decreases access of air oxygen to hot metal in dross, decreases its oxidation and possible thermite reactions.

Ribbing of press head provides increase in surface area of contact with dross, increases energy heat transfer from dross to said head, thus facilitating early cooling of dross and decrease in metal oxidation in dross.

Ribbing of press head provides high specific pressure onto dross and grooving of the dross, facilitating breakage and subsequent supplemental recovery of metal from frozen pressed dross (skull).

There is a frame with a dross compressing head provided with a power drive, particularly, hydraulic cylinder with a rod.

Within compression of hot dross, as a rule with higher metal content in excess of 50%, fine metal particles coagulate and coalesce into coarser particles, and external dross surfaces are metalized and compressed. Herewith, there occurs natural sealing of the gap between said compressing head and skim pan, and vacuum via through hole in said skim pan and drainage hole in the bottom of skim pan, provided that there exists sealing between said saw mould and said skim pan, promotes increase in drainage of liquid metal from hot dross. However, in the case of low metal content in dross, below 50%, metallization and compressing of external surfaces of dross can be inefficient. In such case additional sealing is applied between the dross compressing head and skim pan.

Particularly, in case of additional sealing necessity, the apparatus can comprise additional hermetic cover, hermetically female the rod of hydraulic cylinder with a possibility of sliding along the rod and hermetically to cover the skim pan.

With a purpose to reduce the additional cover movement time, the apparatus can comprise additional hermetic cover, hermetically female the rod of hydraulic cylinder with a possibility of sliding along the rod and hermetically to cover the skim pan by means of pneumatic or/and hydraulic cylinders (from 1 to 4 pcs), or/and electric drive.

With a purpose of additional insulation from the air oxygen and pressure increase from the head side, the apparatus can comprise additional hermetic cover, hermetically female the rod of hydraulic cylinder with a possibility of sliding along the rod and hermetically to cover the skim pan by means of pneumatic or/and hydraulic cylinders (from 1 to 4 pcs), or/and electric drive and, at least one or more through hole in said cover provided a connection for inert gas supply.

The apparatus can comprise one or more vibrators of said skim pan and/or said head, further comprising one or more magneto-hydrodynamic (MHD) pumps facilitating for moving of metal to one or more drainage holes in the bottom of said skim pan.

The head can be hollow with air cooling, which reduces dross cooling time and decreases metal oxidation loss. The walls of said saw mould are preferably made of alloyed steel or cast iron.

BRIEF DESCRIPTION OF THE DRAWINGS

The brief description of the invention is explained referring to the drawings below:

FIG. 1. General front side view of the apparatus for recovery of non-ferrous metal from hot dross provided with through hole in the skim pan bottom with connection for switching on vacuum “manually” just after the positioning of the skim pan inside of the said apparatus by means of a forklift.

FIG. 2. Back side view with a partial section of the apparatus for recovery of non-ferrous metal from hot dross provided with through hole in the skim pan bottom with connection for switching on vacuum, providing an automatic coupling of said skim pan with vacuum source (piping to vacuum pump) at the moment of positioning of the skim pan inside of the said apparatus by means of a forklift.

FIG. 3. General view with a partial section of the apparatus for recovery of non-ferrous metal from hot dross provided with an additional hermetic cover, hermetically female the rod of hydraulic cylinder with a possibility of sliding along the rod and hermetically to cover the skim pan by means of pneumatic or/and hydraulic cylinders (from 1 to 4 pcs), or/and electric drive.

DESCRIPTION OF THE PREFERRED EMBODIMENT

The apparatus comprises the head 1 with rod 2 for compression of hot dross, skimmed from melt surface in furnace/mixer and loaded into skim pan 3, provided with sealing 4 between head 1 and skim pan 3. Skim pan 3 provided with one or more through holes 5 in bottom for drainage of drained metal into lower saw mould 6. Drained metal is collected in the saw mould 6. There are sealing 8 between skim pan 3 and saw mould 6, and at least one through hole 9 with a connection for switching on vacuum through said skim pan bottom 3. There is a frame 7 with a dross compressing head 1 provided with a power drive 11, particularly, hydraulic cylinder with a rod 2.

The head 1 either does not have or has ribbing 12. Skim pan 3 either does not have or has ribbing 13. The dross compressing head 1 could be made hollow with at least two manifolds 14 with air cooling.

One or more vibrators of said skim pan and/or said head, further comprising one or more magneto-hydrodynamic (MHD) pumps 15 [FIG. 2] facilitate for moving of metal to one or more drainage holes 5 in the bottom of said skim pan 3.

In the case of low metal content in dross, below 50%, metallization and compressing of external surfaces of dross can be inefficient. In such case additional sealing 4 is applied between the dross compressing head 1 and skim pan 3.

Particularly, in case of additional sealing necessity, the apparatus can comprise additional hermetic cover 10 [FIG. 2-3], hermetically female the rod 2 of hydraulic cylinder 11 with a possibility of sliding along the rod 2 and hermetically to cover the skim pan 3.

With a purpose to reduce the additional cover movement time, the apparatus can comprise additional hermetic cover 10, hermetically female the rod 2 of hydraulic cylinder 11 with a possibility of sliding along the rod 2 and hermetically to cover the skim pan 3 by means of pneumatic or/and hydraulic cylinders 17 (from 1 to 4 pcs), or/and electric drive [FIGS. 2-3].

With a purpose of additional insulation from the air oxygen and pressure increase from the head side, the apparatus can comprise additional hermetic cover 10, hermetically female the rod 2 of hydraulic cylinder 11 with a possibility of sliding along the rod 2 and hermetically to cover the skim pan 3 by means of pneumatic or/and hydraulic cylinders 17 (from 1 to 4 pcs), or/and electric drive and, at least one or more through hole 16 in said cover providing a connection for inert gas supply.

The apparatus operation is as following: The skimpan 3 is put on the saw mould 6 by means of forklift. Hot dross is to be skimmed from the melting/holding furnace melt surface into the skim pan 3 which is put on the saw mould 6. The set of said skim pan 3 put on the saw mould 6 is to be placed by means of forklift into the apparatus for hot dross compression (press), provided the said seal 8 is located between said skim pan 3 and saw mould 6 and with one or more through holes 9 with connection for switching on vacuum through said skim pan 3 bottom. The head 1 with rod 2 compress the hot dross, and the head 1 can be made hollow with at least two manifolds 14 to be cooled with air.

The sealing 4 between said head 1 and skim pan 3 promote a vacuumization.

In case of additional sealing necessity, the apparatus can comprise additional hermetic cover 10 [FIGS. 2-3], hermetically female the rod 2 of hydraulic cylinder 11 with a possibility of sliding along the rod 2 and hermetically to cover the skim pan 3.

With a purpose to reduce the additional cover 10 movement time, the apparatus can comprise additional hermetic cover 10, hermetically female the rod 2 of hydraulic cylinder 11 with a possibility of sliding along the rod 2 and hermetically to cover the skim pan 3 by means of pneumatic or/and hydraulic cylinders 17 (from 1 to 4 pcs) [FIGS. 3-5], or/and electric drive [FIGS. 2-3],.

The drained metal is to be collected in the said saw mould 6.

In comparison with the prototype, other conditions being equal, vacuum and/or vibrator of head and/or skim pan, and/or MHD pumps facilitate increase in metal recovery from dross.

REFERENCES CITED

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1. Apparatus for recovery of non-ferrous metal from hot dross, preferably aluminium, alloys thereof, magnesium, zinc dross comprising a frame with dross compressing head, a sow mould for collection of drained metal from hot dross and a skim pan, provided with one or more through drainage holes in a bottom, put on a said sow mould, characterized in that provided with at least one through hole with connection for switching on vacuum through said skim pan bottom and/or sow mould, sealing located in the gap between said skim pan and saw mould.
 2. The apparatus of claim 1, further comprising a seal between dross compressing head and skim pan.
 3. The apparatus of claim 1 or 2, wherein comprising a cover with a sealing hermetically female the rod of hydraulic cylinder with a possibility of sliding along the rod and with a sealing hermetically to cover the skim pan.
 4. The apparatus of claim 1 or 2, wherein comprising a cover with a sealing hermetically female the rod of hydraulic cylinder with a possibility of sliding along the rod and with a sealing hermetically to cover the skim pan by means of pneumatic or/and hydraulic cylinders (from 1 to 4 units), or/and electric drive.
 5. The apparatus of claim 1 or 2, wherein comprising a cover with a sealing hermetically female the rod of hydraulic cylinder with a possibility of sliding along the rod and with a sealing hermetically to cover the skim pan by means of pneumatic or/and hydraulic cylinders (from 1 to 4 units), or/and electric drive and, at least one through hole in said cover provided a connection for inert gas supply.
 6. The apparatus of claim 1 or 2, further comprising one or more vibrators of said skim pan and/or said head.
 7. The apparatus of claim 1 or 2, further comprising one or more magneto-hydrodynamic (MEM) pumps for moving of metal to one or more drainage holes in the bottom of said skim pan.
 8. The apparatus of claim 1 or 2, wherein said head is made hollow with at least two manifolds with air cooling.
 9. The apparatus of claim 1 or 2, wherein the head is ribbed with one or more ribs.
 10. The apparatus of claim 1 or 2, wherein the skim pan is ribbed with one or more ribs.
 11. Method for recycling of non-ferrous metal from hot dross, preferably aluminium, alloys thereof, magnesium, zinc dross, comprising the following steps/operations: (a) hot dross skimming into the said apparatus skim pan p.1 or 2, (b) non-ferrous drained metal collection though at least one through hole in said skim pan bottom; (c) mechanically compression of dross by means of force application on said dross between a said head and a skim pan for recovery of non-ferrous metal from dross, metal migration effect to the compressed dross external surface, capsulating internal oxides core between said head and skim pan, drainage of non-ferrous metal portion through skim pan bottom hole/s and preventing oxygen access to dross; and, (d) switching on vacuum to a bottom part of skim pan and/or sow mould, provided with at least one through hole with a vacuum connection and a seal in a gap between skim pan and sow mould, wherein skim pan provided with one or more through holes in a bottom; and, simultaneously with (c) and (d), (e) collection of non-ferrous metal drained through hole in a skim pan bottom; (f) cooling of compressed dross and non-ferrous metal for solidification; to decrease a thermite reaction between non-ferrows metal and oxygen in dross by means of aforementioned dross compression, vacuum effect and metal cooling combination.
 12. Method of claim 11, comprising additional thermal insulation or/and heating of a skim pan bottom with one or more drainage through holes, particularly by means of resistor or induction heater.
 13. Method of claim 11 or 12, wherein vacuum depth in operation (d) is in a range 0.09 MPa to 0.1 k:Pa.
 14. Method of claim 11 or 12, wherein vacuum depth in operation (d) is varied in proportional dependence on mechanical pressure force from said head.
 15. Method of claim 11 or 12, wherein vacuum depth in operation (d) is varied in pulse form, particularly, sinusoidal, squared shape, triangle fmm or/and their combinations.
 16. Method of claim 15, wherein vacuum pulses amplitude, shape, frequency and on-off time ratio are used for dross vibration achievement between said compressmg head and skim pan, including a frequency equal or closer to a mechanical resonance of dross between said compressing head and skim pan. 17 Method of claim 11 or 12, wherein in operation (c) series from 2 to 10sequential dross compressions are made.
 18. Method of claim 11 or 12, including further mechanical breaking of compressed and cooled dross and separation for recycling of solidified non-ferrous metal.
 19. Method of claim 11 or 12, including operation of free non-ferrous metal and oxides separation.
 20. Method of claim 19, wherein a separation operation includes screening for free non-ferrous metal.
 21. Method for recycling of non-ferrous metal from hot dross, preferably aluminium, alloys thereof, magnesium, zinc dross, comprising the following steps/ operations: (a) hot dross skimming into the said apparatus skim pan p. 1 or 2, (b) non-ferrous drained metal collection though at least one hole in said skim pan bottom; (c) mechanically compression of dross by means of force application on said dross between a said head and a skim pan for recovery of non-ferrous metal from dross, metal migration effect towards the compressed dross external surface, capsulating internal oxides core between said head and skim pan, drainage of non-ferrous metal portion through skim pan bottom hole/s and preventing oxygen access to metal in dross; and, (d) switching on vacuum to a bottom part of skim pan and/or sow mould, provided with at least one through hole with a vacuum connection, and a seal in a gap between said skim pan and said sow mold, wherein skim pan provided with one or more through drainage holes in a bottom; and, simultaneously with (c) and (d), (e) collection of non-ferrous metal drained through a hole in a skim pan bottom; (f) cooling of compressed dross and non-ferrous metal for solidification; (e) removal of compressed dross from skim pan; (g) removal of compressed dross from skim pan; (h) mechanical breaking of compressed dross for components separation, including salt or oxides parts of dross; (g) dross components separation; (h) melting of preferably metal containing part with coarse average diameter, dross residue metallic granulates for melted non-ferrows metal segregation from dross residue.
 22. Method of claim 21, including operation of dross residue separation by means of dross salt-oxides parts collection;
 23. Method of claim 21, including dross residue granules melting in sidewell furnace, including a pumping of granulates into the melt under the melt surface by means of MEM or mechanical pump vortex principle. 